KR101332051B1 - Signal processing apparatus, system and method for automatic gain control using the same - Google Patents

Abstract

The present invention relates to a signal processing apparatus, and a system and a method for automatic gain control using the same. The signal processing apparatus comprises: a frequency sweeping unit for outputting a signal (S) to sweep each channel frequency within a given range by a receiver; a signal level detecting unit for detecting a signal level of each channel by reading, from the receiver, a gain value determined when each channel frequency is swept; and a take over point (TOP) adjusting unit for changing a TOP value of the receiver according to the detected signal level of each channel. The signal processing apparatus and the system and the method for automatic gain control according to the present invention are able to improve operational characteristics of a receiver in a strong electric field or a weak electric field. [Reference numerals] (110) Frequency sweeping unit;(120) Signal level detecting unit;(130) TOP adjusting unit

Description

SIGNAL PROCESSING APPARATUS, SYSTEM AND METHOD FOR AUTOMATIC GAIN CONTROL USING THE SAME

The present invention relates to a signal processing device, an automatic gain control system and method using the same, and more particularly, a signal processing device capable of improving linearity and noise characteristics of a receiver in a weak field or a strong field, and an automatic device using the same. A gain control system and method are disclosed.

Typically, electrical devices that process signals perform automatic gain control (AGC) to reduce intermodulation and saturation in the amplifier. In particular, automatic gain control in a receiver of a mobile communication system is used for the purpose of obtaining a signal of a desired level by inputting a signal whose signal level is not constant. That is, when the input signal level is greater than the reference value, the gain value is lowered to prevent signal saturation, and when the input signal level is less than the reference value, the gain value is increased to adjust the output signal to a predetermined level.

In this regard, Korean Patent Application Publication No. 10-2011-0068778 (hereinafter, referred to as a prior art document) published in Korean Laid-Open Patent Publication, low noise amplifying a received signal using a first gain value, the low noise amplified reception Amplifying the signal to a second gain value, determining the first gain value using the strength of the low noise amplified received signal, and using the received signal amplified to the second gain value, the second gain There is proposed an automatic gain control method and apparatus for performing a step of determining a value to ensure the reliability of the automatic gain control.

However, the automatic gain control method and apparatus of the prior art document do not consider the channel environment of the satellite broadcast at all, and it is difficult to receive a signal output from the satellite broadcast station.

In the satellite broadcasting channel environment that outputs a wide frequency signal (950MHz ~ 2150MHz), the strength and weakness of the signal vary greatly depending on the reception area and the weather. In recent years, as the demand for the receiver is gradually increased as the conversion to high-definition digital broadcasting, the satellite broadcasting station transmits a stronger signal than the existing channel. For this reason, interference between a specific channel (hereinafter, referred to as a specific channel) that a user wants to receive and an adjacent channel (hereinafter, referred to as an adjacent channel) is getting worse.

1 is a diagram illustrating a signal level of each channel in the satellite broadcast frequency band. As illustrated in FIG. 1, in a channel environment of satellite broadcasting, adjacent channels having a signal level 20 dBm larger than a signal level of a specific channel may be received. In such a case, the automatic gain control method and apparatus presented in the prior art document cannot prevent the degradation of linearity and noise characteristics of the receiver.

The automatic gain control system is largely classified into an external type automatic gain control system (hereinafter referred to as an external AGC system) and an internal type automatic gain control system (hereinafter referred to as an internal AGC system).

2 is a block diagram of an External AGC system. The external AGC system is the most commonly used AGC system. Referring to FIG. 2, the external AGC system detects a final output signal level of a receiver in a base-band demodulator (not shown), and detects the detected level. The gain controller 14 sets the gain values of the RF amplifiers RFVGA, 11 and IF amplifiers IFVGA 13 according to the final output signal level.

In the external AGC system, since the gain value is set only by the signal after the bandpass filter 12, that is, the signal level of a specific channel, the external AGC system is larger than a specific channel as shown in FIG. 1 in a strong electric field (region where the signal is strong). When the adjacent channel of the signal level comes in, the linearity characteristic of the receiver may deteriorate.

3 is a signal level diagram at each block end of an External AGC system. Here, the vertical axis represents the output signal level (dBm), and the horizontal axis represents each block stage of the external AGC system. For reference, a low noise amplifier (LNA), an attenuator (ATT), and an IF amplifier (IFVGA) are additionally provided in front of the mixer of FIG. 1.

Referring to FIG. 3, a signal level of a specific channel corresponds to a strong electric field at −60 dBm, and a signal level of an adjacent channel is −40 dBm, and a signal level of an adjacent channel is 20 dBm or more greater than that of a specific channel.

In this case, as described above, since the gain value is set by the signal level of the specific channel passed through the bandpass filter 12, the adjacent channel signal is amplified with the same gain value as the specific channel signal. As a result, as shown in FIG. 3, adjacent channel signals before and after the mixer depart from the ideal gain control region, thereby deteriorating the linearity characteristic of the receiver.

4 is a block diagram of an Internal AGC system. Referring to FIG. 4, the Internal AGC system detects the signal level of each amplifier by placing Received Signal Strength Indicator (RSSI) detectors 21a and 22a at the output terminals of the RF amplifier 21 and the IF amplifier 22 inside the receiver, respectively. Then, the gain value of each amplifier is set by itself through the gain controller 23 according to each detected signal level.

As described above, since the gain value of each amplifier is set according to the signal level of each amplifier detected through the RSSI detectors 21a and 22a in the internal AGC system, unlike the external AGC system, the linearity characteristic of the receiver due to the adjacent channel is not degraded. Does not occur. However, since the automatic gain gain control method in the internal AGC system is set according to the signal level of the channel existing in all frequency bands, when adjacent channels of a signal level larger than a specific channel are input as shown in FIG. Noise characteristics of the receiver may be degraded.

5 is a signal level diagram at each block end of an Internal AGC system. Here, the vertical axis represents the output signal level (dBm), and the horizontal axis represents each block stage of the Internal AGC system.

Referring to FIG. 5, a signal level of a specific channel corresponds to a weak field at −80 dBm, and a signal level of an adjacent channel is −60 dBm, and a signal level of an adjacent channel is 20 dBm or more greater than that of a specific channel.

In this case, as described above, since the internal AGC system sets the gain value according to the signal level of the channel existing in the entire frequency band, the signal level of the specific channel is below the minimum level that can be detected by the RSSI detectors 21a and 22a. When dropped, the gain value is also set by the adjacent channel signal rather than by the specific channel signal. As a result, as shown in FIG. 5, the noise characteristic of the receiver is degraded.

Patent Document: Republic of Korea Patent Publication No. 10-2011-0068778

The present invention is to solve the above problems, a signal processing device that can improve the linearity and noise characteristics of the receiver even if the signal level difference between a particular channel and the adjacent channel in a strong field or weak field and automatic using the same It is an object to provide a gain control system and method.

The present invention, devised to achieve the above object, the frequency sweep unit for outputting a signal (S) for each channel frequency is swept (Sweep) through a receiver; A signal level detection unit reading a gain value set at each channel frequency sweep from a receiver to detect a signal level of each channel; And a TOP adjusting unit for changing a take over point (TOP) value of the receiver according to the detected signal level of each channel.

In addition, each channel frequency width within a predetermined period swept by the frequency sweep unit is set to an arbitrary value, provides a signal processing apparatus.

The TOP adjusting unit may further include determining that a difference between a signal level of a specific channel and an adjacent channel is greater than or equal to a first threshold value and that a signal level of a specific channel is greater than or equal to a second threshold value among signal levels of each channel detected by the signal level detector. Provided is a signal processing apparatus for changing a TOP value to a minimum level within a range capable of detecting a signal.

In addition, the TOP adjustment unit, if the signal level difference between the specific channel and the adjacent channel among the signal level of each channel detected by the signal level detection unit is greater than or equal to the first threshold value, the signal level of the specific channel is less than or equal to the third threshold value, A signal processing apparatus is provided which changes the TOP value to a maximum level within a range in which the linearity of the receiver is maintained.

In addition, the signal processing device and the receiver is a signal processing device is a signal processing device that is transmitted to each other through a communication interface line of any one of a universal asynchoronous receiver / transmitter (UART), a serial peripheral interface (SPI), an inter-integrated circuit (I2C) To provide.

In addition, the predetermined period provides a signal processing apparatus, which is a satellite broadcast frequency band.

The present invention devised to achieve the above object comprises: a first amplifier for amplifying a radio frequency (RF) signal received from an antenna; A mixer for downconverting the frequency of the amplified signal; A bandpass filter for selecting and passing a specific channel frequency from down-converted signals; A second amplifier for amplifying and outputting a specific channel signal passed through the band pass filter to the outside; A gain controller for setting gain values of the first and second amplifiers according to a signal applied from the outside; And a signal processing device for changing a take over point (TOP) value of the gain controller according to a signal level of a specific channel and an adjacent channel.

In addition, a local oscillator for generating a predetermined oscillation frequency source according to the external control voltage (Vc) and outputs to the mixer; And a phase locked loop (PLL) for outputting a control voltage (Vc) to the local oscillator, wherein the control voltage (Vc) of the phase locked loop (PLL) is applied by the signal processing device. An automatic gain control system is provided, which varies in accordance with the signal S.

In addition, the signal processing apparatus includes a control voltage Vc of the phase-locked loop PLL such that each channel frequency within a predetermined period is swept through the first amplifier, the mixer, the band pass filter, and the second amplifier. A frequency sweep unit for outputting a variable signal S; A signal level detector for detecting a signal level of each channel by reading a gain value of each amplifier set at each channel frequency sweep from the gain controller; And a TOP adjuster for changing a take over point (TOP) value of the gain controller according to the detected signal level of each channel.

The TOP adjuster may include a signal level difference between a specific channel and an adjacent channel greater than or equal to a first threshold value TH1 among the signal levels of each channel detected by the signal level detector, and the signal level of the specific channel may be a second threshold value. If (TH2) or more, the automatic gain control system is provided, which changes the TOP value to the minimum level within the range in which the signal can be detected.

In addition, the TOP adjuster may include a signal level difference between a specific channel and an adjacent channel less than the first threshold value TH1 among the signal levels of each channel detected by the signal level detector, or the signal level of the specific channel may be a second threshold. If it is less than the value TH2, an automatic gain control system is provided which keeps the TOP value at the existing value.

In addition, the mixer provides an automatic gain control system for outputting an intermediate frequency (IF) band signal by down-converting the frequency of the amplified signal.

The present invention devised to achieve the above object comprises: a first amplifier for amplifying a radio frequency (RF) signal received from an antenna; A mixer for downconverting the frequency of the amplified signal; A bandpass filter for selecting and passing a specific channel frequency from down-converted signals; A second amplifier for amplifying and outputting a specific channel signal passed through the band pass filter to the outside; A gain controller for adjusting a gain value of the first amplifier according to a received signal strength indication (RSSI) value of the first amplifier and setting a gain value of the second amplifier according to the RSSI value of the second amplifier; And a signal processing device for changing a take over point (TOP) value of the gain controller according to a signal level of a specific channel and an adjacent channel.

In addition, a local oscillator for generating a predetermined oscillation frequency source according to the control voltage and outputs to the mixer; And a phase locked loop (PLL) for outputting a control voltage (Vc) to the local oscillator, wherein the control voltage (Vc) of the phase locked loop (PLL) is applied to a signal (S) applied from the signal processing device. Provides an automatic gain control system, which varies accordingly.

In addition, the signal processing apparatus includes a control voltage Vc of the phase-locked loop PLL such that each channel frequency within a predetermined period is swept through the first amplifier, the mixer, the band pass filter, and the second amplifier. A frequency sweep unit for outputting a control signal that varies; A signal level detector for detecting a signal level of each channel by reading a gain value of each amplifier set at each channel frequency sweep from the gain controller; And a TOP adjuster for changing a take over point (TOP) value of the gain controller according to the detected signal level of each channel.

The TOP adjuster may include a signal level difference between a specific channel and an adjacent channel greater than or equal to a first threshold value TH1 and a signal level of a specific channel among a signal level of each channel detected by the signal level detector. Below (TH3), an automatic gain control system is provided that changes the TOP value to the maximum level within the range in which the linearity of the receiver is maintained.

In addition, the TOP adjuster may include a signal level difference between a specific channel and an adjacent channel less than the first threshold value TH1 among the signal levels of each channel detected by the signal level detector, or the signal level of the specific channel may be a third threshold. If the value TH3 is exceeded, an automatic gain control system is provided which keeps the TOP value at the existing value.

The present invention devised to achieve the above object includes a first amplifier, a mixer, a bandpass filter, a second amplifier, a gain controller and a signal processing device, wherein the gain controller is configured according to a signal applied from the outside. An automatic gain control method of an automatic gain control system for setting gain values of first and second amplifiers, the method comprising: (a) detecting the largest signal level (hereinafter, Max.Level value) among the channel signal levels within a predetermined period; step; (b) detecting a signal level (hereinafter, Cur.Level value) of a specific channel; (c) determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1; (d) if the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1 in step (c), determining whether the Cur.Level value is greater than or equal to the second threshold value TH2; ; And (e) if the Cur.Level value is greater than or equal to the second threshold value TH2, changing the TOP value to a minimum level within a range capable of detecting a signal.

In addition, the step (a), (a1) initializing the Max.Level value to an arbitrary value; (a2) sweeping an n-th channel frequency among channels within a predetermined interval; (a3) detecting a signal level (hereinafter n.Level value) of the nth channel; (a4) determining whether the n.Level value is greater than a Max.Level value; (a5) if the n.Level value exceeds the Max.Level value in step (a4), changing the Max.Level value to an n.Level value; And (a6) determining whether the nth channel and the mth channel are the same.

In addition, if the n.Level value is less than or equal to the Max.Level value in step (a4), branching to the step (a6) provides an automatic gain control method.

In step a6, if the n-th channel and the m-th channel are the same, the process of detecting the Max.Level value is terminated. If not, the automatic gain control method branches to the step (a2) by n = n + 1. to provide.

Further, in step (c), the difference between the Cur.Level value and the Max.Level value is less than the first threshold value TH1, or in step (d), the Cur.Level value is the second threshold value TH2. If less, it provides an automatic gain control method that maintains the TOP value at the existing value.

The present invention devised to achieve the above object includes a first amplifier, a mixer, a bandpass filter, a second amplifier, a gain controller and a signal processing device, wherein the gain controller is applied to the RSSI value of the first amplifier. In the automatic gain control method of the automatic gain control system to adjust the gain value of the first amplifier according to the control, and to set the gain value of the second amplifier according to the RSSI value of the second amplifier, (a) each channel signal within a predetermined period Detecting the largest signal level among the levels (hereinafter referred to as Max.Level value); (b) detecting a signal level (hereinafter, Cur.Level value) of a specific channel; (c) determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1; (d) if the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1 in step (c), determining whether the Cur.Level value is less than or equal to the third threshold value TH3; ; And (e) changing the TOP value to a maximum level within a range in which the linearity characteristic of the receiver is maintained if the Cur.Level value is less than or equal to the third threshold value TH3. do.

Further, in step (c), the difference between the Cur.Level value and the Max.Level value is less than the first threshold value TH1, or in step (d), the Cur.Level value is the third threshold value TH3. If it is exceeded, an automatic gain control method is provided to keep the TOP value at the existing value.

According to the signal processing apparatus and the automatic gain control system and method using the same according to the present invention, in the automatic gain control of the external AGC system, the linearity of the receiver even when a neighboring channel having a signal level larger than a specific channel is input in the strong electric field The signal can be amplified while maintaining its characteristics.

In the automatic gain control of the internal AGC system, a signal can be amplified while maintaining a noise characteristic of the receiver even when adjacent channels of a signal level larger than a specific channel enter the weak field.

1 is a diagram illustrating a signal level of each channel in the satellite broadcast frequency band.
2 is a block diagram of an External AGC system.
3 is a signal level diagram at each block end of an External AGC system.
4 is a block diagram of an Internal AGC system.
5 is a signal level diagram in each component of the Internal AGC system.
6 is a block diagram illustrating a signal processing apparatus according to the present invention.
7 is a block diagram of a first automatic gain control system.
8 is a signal level graph of each channel that appears when the TOP value is changed in the first automatic gain control system.
9 is a graph illustrating TOP values changed in the first automatic gain control system.
10 is a configuration block diagram of a second automatic gain control system.
11 is a detail view of the gain controller.
12 is a signal level graph of each channel that appears when the TOP value is changed in the second automatic gain control system.
13 is a graph illustrating a TOP value changed in a second automatic gain control system.
14 is a flowchart of a first automatic gain control method.
15 is a flowchart of a second automatic gain control method.
16 is a flowchart of a method of detecting a Max.Level value.

The advantages and features of the present invention and the techniques for achieving them will be apparent from the following detailed description taken in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. The present embodiments are provided so that the disclosure of the present invention is not only limited thereto, but also may enable others skilled in the art to fully understand the scope of the invention. Like reference numerals refer to like elements throughout the specification.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular forms include plural forms unless otherwise specified in the text. It is to be understood that the terms 'comprise', and / or 'comprising' as used herein may be used to refer to the presence or absence of one or more other components, steps, operations, and / Or additions.

Hereinafter, the configuration and operation effects of the present invention will be described in more detail with reference to the accompanying drawings.

6 is a block diagram illustrating a signal processing apparatus according to the present invention.

Referring to FIG. 6, the signal processing apparatus 100 according to the present invention may include a frequency sweep unit 110, a signal level detector 120, and a TOP adjuster 130.

The frequency sweep unit 110 applies a signal S to the receiver so that each channel frequency within a predetermined period is swept in sequence through a receiver (not shown).

Here, the receiver refers to a receiving device composed of an amplifier, a filter, a mixer, and the like, which amplifies and filters a signal input from an antenna and outputs the signal to an external device (for example, a demodulator). The receiver includes a high frequency signal such as a mobile communication device or a TV tuner. It can be used for any device that receives and processes it. However, since the signal processing apparatus 100 according to the present invention has an object of improving an operation characteristic of a receiver in a satellite broadcasting environment in which signal interference between channels is severe, it is preferable that the receiver is a receiver for satellite broadcasting. It may also be a satellite broadcast frequency band section.

Specifically, the signal S applied to the receiver from the frequency sweep unit 110 varies the oscillation frequency source provided to the mixer (not shown) in the receiver. In this way, as the oscillation frequency source provided to the mixer is changed by the signal S, each channel frequency within a predetermined period may be swept in sequence through the receiver.

In this case, each channel frequency width within a predetermined section that is sequentially swept by the frequency sweep unit 110 may be set to an arbitrary value. Unlike in terrestrial broadcasting, in the case of satellite broadcasting, each channel frequency width is not fixed. For example, each channel frequency width swept through the receiver may be 40 MHz, and thus the oscillation frequency source provided to the mixer may be varied to 1920 MHz, 1960 MHz, 2000 MHz, 2040 MHz, and 2080 MHz.

When each channel frequency within a predetermined period is swept by the frequency sweep unit 110 in turn, the signal level detector 120 reads a gain value set at each channel frequency sweep from the receiver to determine each channel signal level within the predetermined period. Detect.

The signal level detection process of each channel performed by the signal level detector 120 will be described in detail in an automatic gain control system using the signal processing apparatus 100 according to the present invention.

When the signal level detection unit 120 detects each channel signal level in a certain section, the TOP adjustment unit 130 based on this, a specific channel (hereinafter, a specific channel) that a user wants to receive from each channel within a certain section. The take over point (TOP) value of the receiver is changed according to the signal level of the adjacent channel (hereinafter, adjacent channel).

Specifically, when the signal level difference between the specific channel and the adjacent channel is greater than or equal to the first threshold value and the signal level of the specific channel is greater than or equal to the second threshold value, the TOP adjuster 130 minimizes the TOP value within the range in which the signal can be detected. Change to level.

If the signal level difference between the specific channel and the adjacent channel is greater than or equal to the first threshold and the signal level of the specific channel is less than or equal to the third threshold, the TOP adjuster 130 sets the TOP value within a range in which the linearity characteristic of the receiver is maintained. To the maximum level. The meaning of the first to third thresholds will be described in an automatic gain control system using the signal processing apparatus 100 according to the present invention described later.

The communication interface line between the signal processing device and the receiver may be any one of a universal asynchoronous receiver / transmitter (UART), a serial peripheral interface (SPI), and an inter-integrated circuit (I2C).

Now, the first automatic gain control system using the signal processing apparatus according to the present invention will be described.

7 is a block diagram of a first automatic gain control system.

Referring to FIG. 7, the first automatic gain control system 200 includes a first amplifier 210, a mixer 220, a bandpass filter 230, a second amplifier 240, a gain controller 250, and a signal. The processing device 100 may be included. In addition, a local oscillator 260 and a phase locked loop (PLL, 270) may be further included.

The first amplifier 210 amplifies a radio frequency (RF) signal received from an antenna. Since the first automatic gain control system 200 using the signal processing apparatus 100 according to the present invention is intended to improve receiver operating characteristics in a satellite broadcasting environment, the frequency band of the high frequency (RF) signal here is 950 MHz to 2150 MHz. Can be

The first amplifier 210 may be connected in multiple stages, some of which may be configured as a low noise amplifier (LNA) to lower the noise figure of the entire receiver. In addition, an attenuator may be further provided at the front or rear end of the first amplifier 210 to suppress saturation of the signal and maintain stable reception performance.

The mixer 220 down-converts the frequency of the high frequency signal amplified by the first amplifier 210. In this case, the signal down-converted by the mixer 220 may be an intermediate frequency (IF) band signal.

The local oscillator 260 generates a predetermined oscillation frequency source according to an external control voltage Vc and outputs it to the mixer 220, and the PLL 270 sends the control voltage Vc to the local oscillator 260. ) That is, the local oscillator 260 generates an oscillation frequency source (eg, 1920 MHz, 1960 MHz, 2000 MHz, 2040 MHz, 2080 MHz) corresponding to the magnitude of the control voltage Vc output from the PLL 270. Provided at 220.

The bandpass filter 230 selects and passes a specific channel frequency from the signal down-converted by the mixer 220.

The specific channel signal passing through the bandpass filter 230 is amplified by the second amplifier 240 and output to the outside (eg, a demodulator). Since the frequency band of the signal down-converted by the mixer 220 may be an intermediate frequency band, the second amplifier 240 may be an IF amplifier. In addition, the second amplifier 240 may be connected in multiple stages as in the first amplifier 210, some of which may be located in front of the band pass filter 230.

The gain controller 250 sets gain values of the first and second amplifiers. The signal level output from the first and secondary amplifiers is determined, respectively. Accordingly, the gain value is set smaller if the input signal level is greater than the predetermined output signal level, and the gain value is smaller if the input signal level is smaller than the predetermined output signal level. This is set large.

In the first automatic gain control system 200, the gain controller 250 sets gain values of the first and second amplifiers according to a signal applied from the outside. Here, the signal applied from the outside means a bit signal output from a demodulator (not shown) which is located outside the receiver and converts an analog signal output from the second amplifier 240 to a digital signal. Therefore, the first automatic gain control system 200 of the present invention according to the present invention, the automatic gain control of the external (External) method for automatically controlling the gain value of the first and second amplifiers according to the signal level of the final output It may be a system (hereinafter, an external AGC system).

The signal processing apparatus 100 changes a take over point (TOP) value of the gain controller 250 according to a signal level of a specific channel and an adjacent channel.

The signal processing apparatus 100 may include a frequency sweep unit 110, a signal level detector 120, and a TOP adjuster 130.

The frequency sweep unit 110, such that each channel frequency within a predetermined period is swept through the first amplifier 210, the mixer 220, the band pass filter 230 and the second amplifier 240, The signal S for varying the control voltage Vc of the PLL 270 is applied.

That is, the magnitude of the control voltage Vc of the PLL 270 is varied by the signal S applied from the frequency sweep unit 110, and the local oscillator 260 is configured to vary the control voltage Vc. An oscillation frequency source (eg, 1920 MHz, 1960 MHz, 2000 MHz, 2040 MHz, 2080 MHz) corresponding to the magnitude is generated in turn and provided to the mixer 220. The signal received through the antenna is mixed with each oscillation frequency source (eg, 1920 MHz, 1960 MHz, 2000 MHz, 2040 MHz, 2080 MHz) by the mixer 260 and down-converted, and the down-converted signal is converted into the By passing through the bandpass filter 230 and the second amplifier 240, each channel frequency within a predetermined period is swept.

The signal level detector 120 reads a gain value of each amplifier set at each channel frequency sweep from the gain controller 250 to detect a signal level of each channel.

In the external AGC system, the gain value of each amplifier is set by the final output level and the final output level is preset by a constant value. Reading from the gain controller 250 may indirectly determine the signal level of each channel.

The TOP adjuster 130 changes a take over point value of the gain controller 250 according to the detected signal level of each channel.

FIG. 8 is a signal level graph of each channel appearing when the TOP value is changed in the first automatic gain control system, and FIG. 9 is a graph illustrating the TOP value changed in the first automatic gain control system.

As illustrated in FIG. 8, the TOP adjuster 130 has a signal level difference between a specific channel and an adjacent channel in the signal level of each channel detected by the signal level detector 120 is greater than or equal to the first threshold value TH1. If the signal level of the specific channel is greater than or equal to the second threshold value TH2, as shown in FIG.

The external AGC system has a problem of linearity characteristics of a receiver when an adjacent channel of a signal level larger than a specific channel is received in a strong electric field, so the first threshold value TH1 is a receiver characteristic due to a difference in signal levels of a specific channel and an adjacent channel. This means the lowest threshold level that can be degraded, and the second threshold value TH2 means the lowest level in the signal range divided by the strong electric field.

If the first threshold value TH1 is too small, the amount of calculation may increase, thereby overloading the system. On the contrary, if the first threshold value TH1 is too large, the operation reliability of the system cannot be guaranteed. Therefore, the first threshold value TH1 is within an appropriate range. It is preferable to set at. In general, the first threshold value TH1 may be 20 dBm, and the second threshold value TH2 may be −60 dBm.

As described above, the first automatic gain control system 200, which is an external AGC system, changes linearity of the receiver to a minimum level within a range capable of detecting a signal when an adjacent channel having a larger signal level comes in a strong electric field. It can keep the characteristics.

On the other hand, even if a particular channel corresponds to a strong electric field, that is, even if the second threshold value (TH2) or more, the TOP adjuster 130, if the signal level difference between the specific channel and the adjacent channel is less than the first threshold value (TH1). Since the linearity characteristic of the receiver is not deteriorated due to the signal level of the adjacent channel, the TOP value is maintained at the existing value.

Further, even if the signal level difference between the specific channel and the adjacent channel is greater than or equal to the first threshold value TH1, if the specific channel is less than the second threshold value TH2, the linearity characteristic of the receiver may not be degraded. ) Keeps the TOP value at the existing value.

Now, a second automatic gain control system using the signal processing apparatus according to the present invention will be described.

10 is a configuration block diagram of a second automatic gain control system.

Referring to FIG. 10, the second automatic gain control system 300 includes a first amplifier 310, a mixer 320, a bandpass filter 330, a second amplifier 340, a gain controller 350, and a signal. The processing device 100 may be included. In addition, it may further include a local oscillator 360 and a PLL (370). Here, since the first amplifier 310, the mixer 320, the band pass filter 330, the second amplifier 340, the local oscillator 360 and the PLL 370 has been described above, detailed description thereof will be omitted. Shall be.

The gain controller 350 sets gain values of the first and second amplifiers. The signal level output from the first and secondary amplifiers is determined, respectively, and accordingly, the gain value is set lower if the input signal level is greater than the predetermined output signal level, and the gain value if the input signal level is smaller than the predetermined output signal level. Is set high.

In the second automatic gain control system 300, the gain controller 350 may obtain a gain value of the first amplifier 310 according to a received signal strength indication (RSSI) value of the signal output from the first amplifier 310. And adjust the gain of the second amplifier 340 according to the RSSI value of the signal output from the second amplifier 340. Therefore, the second automatic gain control system 300 may be an internal automatic gain control system (hereinafter referred to as an internal AGC system) that automatically controls gain values of the respective amplifiers according to signal levels of the respective amplifiers. .

In the second automatic gain control system 300, a first RSSI detector 310a may be further connected to an output end side of the first amplifier 310 to detect an RSSI value of the first amplifier 310. Similarly, a second RSSI detector 340a may be further connected to the output terminal side of the second amplifier 340 to detect the RSSI value of the second amplifier 340.

The signal processing apparatus 100 changes a take over point (TOP) value of the gain controller 350 according to a signal level of a specific channel and an adjacent channel.

The signal processing apparatus 100 may include a frequency sweep unit 110, a signal level detector 120, and a TOP adjuster 130.

The frequency sweep unit 110 sweeps each channel frequency within a predetermined period through the first amplifier 310, the mixer 320, the bandpass filter 330, and the second amplifier 340. A signal S for varying the control voltage Vc of the PLL 370 is applied.

The process of sweeping each channel frequency within a predetermined period by the frequency sweep unit 110 is the same as that of the first automatic gain control system 200 described above.

The signal level detector 120 reads a gain value of each amplifier set at each channel frequency sweep from the gain controller 350 to detect a signal level of each channel.

In the internal AGC system, gain values of the respective amplifiers 310 and 340 are controlled by the RSSI detectors 310a and 340a at the output terminal of each amplifier, and the output level is changeable by the TOP adjuster 130.

FIG. 11 is a detailed view of a gain controller. For example, the first amplifier 310 converts an analog voltage from the first RSSI detector 310a into a digital signal through a comparator 351 and a counter 352. The gain of the first amplifier 310 may be discretely controlled through the digital signal. Although not shown in the drawing, the second amplifier 340 may also control the gain value discretely in this manner. Since the output levels of the first amplifier 310 and the second amplifier 340 are preset to a constant value, the gain value set at each channel frequency sweep is a digital bit signal generated to match the preset output level. Reading from the gain controller 350 may indirectly determine the signal level of each channel.

The TOP adjuster 130 changes a take over point value of the gain controller 350 according to the detected signal level of each channel.

12 is a signal level graph of each channel that appears when the TOP value is changed in the second automatic gain control system, and FIG. 13 is a graph illustrating the TOP value changed in the second automatic gain control system.

As illustrated in FIG. 12, the TOP adjuster 130 determines that a signal level difference between a specific channel and an adjacent channel is greater than or equal to a first threshold value TH1 in the signal level of each channel detected by the signal level detector 120. If the signal level of the channel is less than or equal to the third threshold value TH3, the TOP value is changed to the maximum level TOP 'within the range in which the linearity characteristic of the receiver is maintained, as shown in FIG.

Since the internal AGC system has a problem of noise characteristics of a receiver when adjacent channels of a signal level larger than a specific channel are received in the weak electric field, the first threshold value TH1 is a receiver characteristic due to a difference in signal levels of a specific channel and an adjacent channel. This means the lowest threshold level that can be degraded, and the third threshold value TH3 means the highest level in the signal range divided by the weak electric field. Here, the first threshold value TH1 may be 20 dBm, and the third threshold value TH3 may be −80 dBm.

As described above, the second automatic gain control system 300, which is an internal AGC system, changes the TOP value to the maximum level within the range in which the linearity characteristic of the receiver is maintained when an adjacent channel of a higher signal level comes in the weak electric field. The noise characteristic of the receiver can be maintained.

On the other hand, even if a particular channel corresponds to a weak electric field, the TOP adjuster 130 is adjacent if the signal level difference between the specific channel and the adjacent channel is less than the first threshold value TH1 even if it is less than or equal to the third threshold value TH3. Because there is no risk of deterioration of receiver characteristics due to the signal level of the channel, we maintain the TOP value at the existing value.

Further, even if the signal level difference between the specific channel and the adjacent channel is greater than or equal to the first threshold value TH1, if the specific channel exceeds the third threshold value TH3, the noise characteristic of the receiver may not be degraded. ) Keeps the TOP value at the existing value.

Now, the first automatic gain control method using the signal processing apparatus according to the present invention will be described. The first automatic gain control method using the signal processing apparatus according to the present invention is performed in the aforementioned first automatic control gain control system, that is, the External AGC system.

14 is a flowchart of a first automatic gain control method.

Referring to FIG. 14, the first automatic gain control method first detects a signal level (hereinafter, Max.Level value) among the channel signal levels within a predetermined period (S110). A method of detecting the Max.Level value will be described later.

If the Max.Level value is detected, a step of detecting a signal level (hereinafter referred to as Cur.Level value) of a specific channel is performed (S120).

In the external AGC system, the gain value of each amplifier is set by the final output level and the final output level is preset by a constant value. Reading from the gain controller 250 may indirectly determine the signal level of each channel.

When the Cur.Level value is detected, a step of determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1 is performed (S130). Here, the first threshold value TH1 means the lowest threshold level at which the receiver characteristic may be degraded due to a difference in signal levels between a specific channel and an adjacent channel.

If it is determined in step S130 that the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1, the method determines whether the Cur.Level value is greater than or equal to the second threshold value TH2. (Step S140). Here, the second threshold value TH2 means the lowest level in the signal range divided by the strong electric field.

If the Cur.Level value is greater than or equal to the second threshold value TH2, the step of changing the TOP value to the minimum level within the range in which the signal can be detected is performed (S150).

As described above, according to the first automatic gain control method of the external AGC system, the linearity characteristic of the receiver is changed by changing the TOP value to the minimum level within a range where signal detection is possible even when a neighboring channel having a larger signal level comes in the strong electric field. It can be maintained.

If the difference between the Cur.Level value and the Max.Level value is less than the first threshold value TH1 in step S130, or if the Cur.Level value is less than the second threshold value TH2 in step S140, the TOP value is determined. Keep the old value.

Now, a second automatic gain control method using the signal processing apparatus according to the present invention will be described. The second automatic gain control method using the signal processing apparatus according to the present invention is performed in the aforementioned second automatic control gain control system, that is, the Internal AGC system.

15 is a flowchart of a second automatic gain control method.

Referring to FIG. 15, the second automatic gain control method of the present invention first performs a step of detecting a Max.Level value (S210). A method of detecting the Max.Level value will be described later.

If the Max.Level value is detected, a Cur.Level value is detected (S220).

In the internal AGC system, the gain value of each amplifier is set by the output level of each amplifier and the output level of each amplifier is set to a constant value. Therefore, the gain value set at each channel frequency sweep is set to the bit of the demodulator (not shown). When the signal is read from the gain controller 350 through a signal, the signal level of each channel may be indirectly known.

When the Cur.Level value is detected, a step of determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1 is performed (S230). Here, the first threshold value TH1 means the lowest threshold level at which the receiver characteristic may be degraded due to a difference in signal levels between a specific channel and an adjacent channel.

If it is determined in step S230 that the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1, determining whether the Cur.Level value is less than or equal to the third threshold value TH3. (S240). Here, the third threshold value TH3 means the highest level in the signal range divided by the weak electric field.

If the Cur.Level value is less than or equal to the third threshold value TH3, a step of changing the TOP value to the maximum level within the range in which the linearity characteristic of the receiver is maintained is performed (S250).

As described above, according to the second automatic gain control method of the internal AGC system, even when adjacent channels of a higher signal level are introduced in the weak field, the receiver is changed to a maximum level within a range where the linearity characteristic of the receiver is maintained. Noise characteristics can be maintained.

On the other hand, if the difference between the Cur.Level value and the Max.Level value in the step S230 is less than the first threshold value (TH1), or if the Cur.Level value is greater than the third threshold value (TH3) in step S240 the TOP value Keep the old value.

Now, the method of detecting the Max.Level value in steps S110 and S210 will be described.

FIG. 16 is a flowchart of a method for detecting a Max.Level value. Referring to FIG. 16, the method for detecting a Max.Level value is performed by first initializing a Max.Level value to an arbitrary value (S10). Here, the arbitrary value becomes an arbitrary reference value for comparison with the signal level of each channel detected in a later step.

Next, a step of sweeping the n-th channel frequency among the channels within a predetermined period is performed (S20).

The nth channel means a channel corresponding to the lowest frequency in the channel frequency to be swept. Therefore, the smaller n is able to sweep a wider range of frequencies. However, if n is too small, the amount of calculation may increase and the system may be overloaded.

Next, a step of detecting a signal level (hereinafter, referred to as n.Level value) of the nth channel is performed (S30). This may be performed in the same manner as detecting the Cur.Level value in the step S120 or S220.

Next, the method determines whether the n.Level value is greater than the Max.Level value (S40). In order to detect the highest signal level among the channels within a certain period, it is determined whether the detected signal level of each channel is greater than the Max.Level value initialized to a value arbitrarily in step S10.

If the n.Level value is greater than the Max.Level value in step S40, changing the Max.Level value to an n.Level value is performed (S50).

As such, when the Max.Level value initialized to an arbitrary value in step S10 is changed to an n.Level value larger than an arbitrary value, the changed Max.Level value becomes a reference value compared with a signal level of a channel which is subsequently swept. .

Next, a step of determining whether the n th channel and the m th channel are the same is performed (S60).

The m-th channel means a channel corresponding to the highest frequency in the channel frequency to be swept. Therefore, as m is larger, a wider range of frequencies can be swept. However, if m is too large, the amount of calculation may increase and the system may be overloaded.

Next, if the n th channel and the m th channel are the same in step S60, the process of detecting the Max.Level value ends. If the n-th channel and the m-th channel are not the same, the process branches to step S20, and n = n + 1 so that the next channel frequency can be swept. Accordingly, all channel frequencies to be swept from the nth channel frequency to the mth channel frequency may be swept in sequence.

On the other hand, if the n.Level value is less than or equal to the Max.Level value in step S40, the process proceeds to step a60 to terminate the Max.Level value detection process without changing the Max.Level value or the next channel frequency is swept. To be possible.

The foregoing detailed description is illustrative of the present invention. In addition, the foregoing description merely shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, it is possible to make changes or modifications within the scope of the concept of the invention disclosed in this specification, the disclosure and the equivalents of the disclosure and / or the scope of the art or knowledge of the present invention. The foregoing embodiments are intended to illustrate the best mode contemplated for carrying out the invention and are not intended to limit the scope of the present invention to other modes of operation known in the art for utilizing other inventions such as the present invention, Various changes are possible. Accordingly, the foregoing description of the invention is not intended to limit the invention to the precise embodiments disclosed. It is also to be understood that the appended claims are intended to cover such other embodiments.

100: signal processing apparatus according to the present invention
110: frequency sweep section
120: signal level detector
130: TOP adjustment unit
200: first automatic gain control system
300: second automatic gain control system
210, 310: first amplifier
310a: first RSSI detector
220, 320: Mixer
230, 330: band pass filter
240, 340: second amplifier
340a: second RSSI detector
250, 350: gain controller
260, 360: Local Oscillator
270, 370: PLL

Claims (25)

delete delete A frequency sweep unit for outputting a signal S for sweeping each channel frequency within a predetermined period through the receiver;
A signal level detection unit reading a gain value set at each channel frequency sweep from a receiver to detect a signal level of each channel; And
A TOP adjuster for changing a take over point (TOP) value of the receiver according to the detected signal level of each channel;
The TOP adjuster may include a TOP value if a difference between signal levels of a particular channel and an adjacent channel is greater than or equal to a first threshold value and a signal level of a particular channel is greater than or equal to a second threshold value among signal levels of each channel detected by the signal level detector. Changing the signal to a minimum level within a range capable of detecting a signal.
A frequency sweep unit for outputting a signal S for sweeping each channel frequency within a predetermined period through the receiver;
A signal level detection unit reading a gain value set at each channel frequency sweep from a receiver to detect a signal level of each channel; And
A TOP adjuster for changing a take over point (TOP) value of the receiver according to the detected signal level of each channel;
The TOP adjusting unit may include a TOP value if a difference between signal levels of a specific channel and an adjacent channel is greater than or equal to a first threshold value and a signal level of a specific channel is less than or equal to a third threshold value among the signal levels of each channel detected by the signal level detector. Changing the signal to a maximum level within a range in which the linearity of the receiver is maintained.
The method according to claim 3 or 4,
The signal processing device and the receiver are signaled to each other via a communication interface line of any one of a universal asynchoronous receiver / transmitter (UART), a serial peripheral interface (SPI), and an inter-integrated circuit (I2C),
Signal processing device.
The method according to claim 3 or 4,
The predetermined section is a satellite broadcast frequency band,
Signal processing device.
A first amplifier for amplifying a radio frequency (RF) signal received from an antenna;
A mixer for downconverting the frequency of the amplified signal;
A bandpass filter for selecting and passing a specific channel frequency from down-converted signals;
A second amplifier for amplifying and outputting a specific channel signal passed through the band pass filter to the outside;
A gain controller for setting gain values of the first and second amplifiers according to a signal applied from the outside; And
And a signal processing device for changing a take over point (TOP) value of the gain controller according to a signal level of a specific channel and an adjacent channel.
The signal processing apparatus includes a signal level difference between a specific channel and an adjacent channel among the signal levels of each channel detected by the signal level detecting unit in the signal processing apparatus, being greater than or equal to the first threshold value TH1, and the signal level of the specific channel being second. The automatic gain control system which changes a TOP value to the minimum level in the range which can detect a signal if it is more than threshold value TH2.
The method of claim 7, wherein
A local oscillator generating a predetermined oscillation frequency source according to an external control voltage Vc and outputting the oscillation frequency source to the mixer; And
And a phase locked loop (PLL) for outputting a control voltage Vc to the local oscillator.
The control voltage Vc of the phase locked loop PLL varies according to the signal S applied from the signal processing apparatus.
Automatic gain control system.
The method of claim 8,
The signal processing device,
The signal S for varying the control voltage Vc of the phase-locked loop PLL such that each channel frequency within a predetermined period is swept through the first amplifier, the mixer, the bandpass filter, and the second amplifier. An output frequency sweep unit;
A signal level detector for detecting a signal level of each channel by reading a gain value of each amplifier set at each channel frequency sweep from the gain controller; And
A TOP adjuster for changing a take over point value of the gain controller according to the detected signal level of each channel;
/ RTI >
Automatic gain control system.
delete The method of claim 9,
The TOP adjustment unit,
If the signal level difference between the specific channel and the adjacent channel among the signal levels of each channel detected by the signal level detector is less than the first threshold value TH1 or if the signal level of the specific channel is less than the second threshold value TH2, To keep the TOP value at the existing value,
Automatic gain control system.
The method of claim 7, wherein
The mixer includes:
Outputting an intermediate frequency (IF) band signal by down-converting the frequency of the amplified signal,
Automatic gain control system.
A first amplifier amplifying a radio frequency (RF) signal received from the antenna;
A mixer for downconverting the frequency of the amplified signal;
A bandpass filter for selecting and passing a specific channel frequency from down-converted signals;
A second amplifier for amplifying and outputting a specific channel signal passed through the band pass filter to the outside;
A gain controller for adjusting a gain value of the first amplifier according to a received signal strength indication (RSSI) value of the first amplifier and setting a gain value of the second amplifier according to the RSSI value of the second amplifier; And
And a signal processing device for changing a take over point (TOP) value of the gain controller according to a signal level of a specific channel and an adjacent channel.
The signal processing apparatus includes a signal level difference between a specific channel and an adjacent channel among the signal levels of each channel detected by the signal level detecting unit in the signal processing apparatus, being greater than or equal to the first threshold value TH1, and the signal level of the specific channel being third. The automatic gain control system, if it is below the threshold TH3, changes the TOP value to the maximum level within the range in which the linearity of the receiver is maintained.
The method of claim 13,
A local oscillator generating a predetermined oscillation frequency source according to a control voltage and outputting the oscillation frequency to the mixer; And
A phase locked loop (PLL) for outputting a control voltage (Vc) to the local oscillator,
The control voltage Vc of the phase locked loop PLL varies according to the signal S applied from the signal processing apparatus.
Automatic gain control system.
15. The method of claim 14,
The signal processing device,
Outputting a control signal for varying the control voltage (Vc) of the phase-locked loop (PLL) to sweep each channel frequency within a predetermined period through the first amplifier, mixer, band pass filter and the second amplifier Frequency sweep unit;
A signal level detector for detecting a signal level of each channel by reading a gain value of each amplifier set at each channel frequency sweep from the gain controller; And
A TOP adjuster for changing a take over point value of the gain controller according to the detected signal level of each channel;
/ RTI >
Automatic gain control system.
delete The method of claim 15,
The TOP adjustment unit,
If the signal level difference between the specific channel and the adjacent channel among the signal levels of each channel detected by the signal level detector is less than the first threshold value TH1 or if the signal level of the specific channel is greater than the third threshold value TH3, To keep the TOP value at the existing value,
Automatic gain control system.
A first amplifier, a mixer, a bandpass filter, a second amplifier, a gain controller, and a signal processing device, wherein the gain controller automatically sets gains of the first and second amplifiers according to a signal applied from the outside. In the automatic gain control method of the system,
(a) detecting the largest signal level (hereinafter referred to as Max.Level value) among the channel signal levels in the predetermined section;
(b) detecting a signal level (hereinafter, Cur.Level value) of a specific channel;
(c) determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1;
(d) if the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1 in step (c), determining whether the Cur.Level value is greater than or equal to the second threshold value TH2; ; And
(e) if the Cur.Level value is greater than or equal to a second threshold value TH2, changing the TOP value to a minimum level within a range capable of detecting a signal;
/ RTI >
Automatic gain control method.
The method of claim 18,
The step (a)
(a1) initializing the Max.Level value to an arbitrary value;
(a2) sweeping an n-th channel frequency among channels within a predetermined interval;
(a3) detecting a signal level (hereinafter n.Level value) of the nth channel;
(a4) determining whether the n.Level value is greater than a Max.Level value;
(a5) if the n.Level value exceeds the Max.Level value in step (a4), changing the Max.Level value to an n.Level value; And
(a6) determining whether the nth channel and the mth channel (wherein the mth channel corresponds to the highest frequency in the channel frequency to be swept) are the same;
Through
Automatic gain control method.
The method of claim 19,
If the n.Level value is less than the Max.Level value in the step (a4), branching to the step (a6),
Automatic gain control method.
The method of claim 19,
In the step (a6), if the n-th channel and the m-th channel is the same, the process of detecting the Max.Level value is terminated, and if not equal, n = n + 1 to branch to the (a2) step,
Automatic gain control method.
The method of claim 18,
If the difference between the Cur.Level value and the Max.Level value in the step (c) is less than the first threshold value (TH1), or if the Cur.Level value is less than the second threshold value (TH2) in the step (d) To keep the TOP value at the existing value,
Automatic gain control method.
And a first amplifier, a mixer, a bandpass filter, a second amplifier, a gain controller, and a signal processing device, wherein the gain controller adjusts a gain value of the first amplifier according to the RSSI value of the first amplifier, and the second amplifier. In the automatic gain control method of the automatic gain control system for setting the gain value of the second amplifier in accordance with the RSSI value of the amplifier,
(a) detecting the largest signal level (hereinafter referred to as Max.Level value) among the channel signal levels in the predetermined section;
(b) detecting a signal level (hereinafter, Cur.Level value) of a specific channel;
(c) determining whether a difference between the Cur.Level value and the Max.Level value is equal to or greater than a first threshold value TH1;
(d) if the difference between the Cur.Level value and the Max.Level value is greater than or equal to the first threshold value TH1 in step (c), determining whether the Cur.Level value is less than or equal to the third threshold value TH3; ; And
(e) if the Cur.Level value is less than or equal to the third threshold value TH3, changing the TOP value to a maximum level within a range in which the linearity characteristic of the receiver is maintained;
/ RTI >
Automatic gain control method.
24. The method of claim 23,
In step (c), if the difference between the Cur.Level value and the Max.Level value is less than the first threshold value TH1, or in step (d), the Cur.Level value is greater than the third threshold value TH3. To keep the TOP value at the existing value,
Automatic gain control method. The method according to claim 3 or 4,
Each channel frequency width within a predetermined period swept by the frequency sweep unit is set to an arbitrary value,
Signal processing device.

Images